Influence of Blending Canola, Palm, Soybean, and Sunflower Oil

Oct 2, 2008 - Preparation of Fatty Acid Methyl Esters from Osage Orange (Maclura pomifera) Oil and Evaluation as Biodiesel. Bryan R. Moser , Fred J. E...
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Energy & Fuels 2008, 22, 4301–4306

4301

Influence of Blending Canola, Palm, Soybean, and Sunflower Oil Methyl Esters on Fuel Properties of Biodiesel† Bryan R. Moser* United States Department of Agriculture, Agricultural Research SerVice, National Center for Agricultural Utilization Research, 1815 North UniVersity Street, Peoria, Illinois 61604 ReceiVed July 24, 2008. ReVised Manuscript ReceiVed August 25, 2008

Single, binary, ternary, and quaternary mixtures of canola (low erucic acid rapeseed), palm, soybean, and sunflower (high oleic acid) oil methyl esters (CME, PME, SME, and SFME, respectively) were prepared, and important fuel properties were measured, such as oil stability index (OSI), cold filter plugging point (CFPP), cloud point (CP), pour point (PP), kinematic viscosity (40 °C), lubricity, acid value (AV), and iodine value (IV). The fuel properties of SME were improved through blending with CME, PME, and SFME to satisfy the IV (6 h) specifications contained within EN 14214, the biodiesel standard from the European Committee for Standardization. SME was satisfactory according to ASTM D6751, the American biodiesel standard, with regard to OSI (>3 h). The CFPP of PME was improved by up to 15 °C through blending with CME. Statistically significant relationships were elucidated between OSI and IV, OSI and saturated fatty acid methyl ester (SFAME) content, OSI and CFPP, CFPP and IV, and CFPP and SFAME content. However, the only relationship of practical significance was that of CFPP versus SFAME content when SFAME content was greater than 12 wt %.

1. Introduction Biodiesel (BD), an alternative fuel composed of monoalkyl esters of long-chain fatty acids prepared from vegetable oils or animal fats, has attracted considerable interest as a substitute or blend component for ultra-low sulfur diesel fuel (ULSD, SFME > PME (highest CP, PP, and CFPP values, Table 2), which was roughly found to inversely follow saturated FAME content: PME (48.2%) > SME (14.6%) > SFME (9.8%) > CME (7.7%). The trend for oxidative stability, as measured by OSI (EN 14112), was found to be PME (best) > CME ∼ SFME > SME (lowest OSI value, Table 2). All samples, with the exception of SME (5.0 h), were satisfactory with respect to the oxidative stability specification in EN 14214 (OSI > 6 h, EN 14112). SME was satisfactory according to the ASTM D6751 requirement (OSI > 3 h, EN 14112). The lower oxidative stability of SME in comparison to the other methyl esters was due to the disproportionately high polyunsaturated FAME content of SME. Polyunsaturated FAME undergo oxidative degradation at significantly faster rates than monounsaturated or saturated methyl esters. For instance, the relative rates of oxidation of the unsaturates were determined to be 1 for oleates, 41 for linoleates, and 98 for linolenates.25 The kinematic viscosities (40 °C) of all methyl esters were within ASTM D6751 and EN 14214 specifications (Table 2) and yielded the following trend: SME < CME < PME < SFME (highest viscosity). This result is somewhat surprising because saturated methyl esters, of which PME had the greatest amount, are known to be more viscous than unsaturated methyl esters.8,26 Lastly, all methyl esters displayed excellent lubricity, as evidenced by short wear scar lengths (